KR100406015B1 - Single ply psa labels for battery applications - Google Patents

Abstract

Axis, and an elongated peripheral case 16 that includes a core 12 that provides electrical energy of direct current. Wherein the label is formed of a heat shrinkable polymeric film having an outer surface and an inner surface that is transparent, self-supporting and oriented substantially in one axis, the width of the film being sufficient to surround the battery case, The first and second sides extending parallel to the axis of the battery and at least adjacent to each other at opposite ends of the cell, the width of the cell being greater than the opposite end, and the opposite end of the cell And provides the wrapping third and fourth sides. An alkaline, electrically non-conductive, opaque coloring layer is applied to the inner surface of the support layer and is supported by the support layer. An electrically non-conductive and pressure-sensitive adhesive layer is applied over the colored layer at least along the first and second sides. The pressure-sensitive adhesive may have a peeling adhesive strength enough to prevent the applied label from being lifted from the case of the battery and to prevent relative movement of the first side attached to the battery case when the supporting layer applied by the adhesive shrinks Lt; / RTI >

Description

[0001] SINGLE PLY PSA LABELS FOR BATTERY APPLICATIONS [0002]

Batteries are the most widely used portable power source. Such batteries include rotary lamps, tool batteries, toy batteries, and facility batteries. Batteries come in a variety of shapes and configurations and vary in output voltage. The batteries can be used alone or in combination. The most widely used sizes are AA, AAA, C, D and 9-volt batteries. AA, AAA, C, and D size batteries use at least one taut cylindrical metal case with different configurations. The cylindrical case serves as a positive electrode end and a negative electrode end. The anode is separated from the cathode by an insulator.

In earlier cells, the graphics used to inform the consumer of battery information were engraved on the battery case. Then, the graphic was engraved on a metal paper wrapping the battery case. Such metal paper is now largely replaced by a label of the system using a multilayer polymer shrink film. Among these, the most widely used polymer raw material is polyvinyl chloride. The configuration of the multi-layer is referred to in the art as " triplex " and " duplex " configurations, and the triple configuration is the most widely used.

As shown in the figure labeled " prior art ", the triple configuration is heat shrinkable, and the metal layer 4, which is typically formed by vapor deposition over a self-supporting first polymer film layer 2, On top of which a second polymer film layer 2 'which is in turn heat shrinkable and self-supporting, a graphic layer 6 and another polymer film layer which is heat-shrinkable and self-supporting which is the uppermost protective layer 2 "). A pressure-sensitive adhesive layer 8 is applied to the lower surface of the film layer 2. The pressure-

In the duplex configuration, the polymer layer 2 'having the first intermediate heat shrinkability is removed, and the metal layer 4, the colored layer 6, and the heat shrinkable layer 6' are formed on the polymer film layer 2 having the first heat- The polymer film layer 2 having heat shrinkability is again coated on its lower surface with the pressure-sensitive adhesive layer 8. In particular, a self-supporting polymer having heat shrinkability For each configuration where the adhesion between the layer and the metal layer is weak, it has been common practice to use an adhesive film to increase the adhesion. For example, the multilayer film adhesive label construction is disclosed in Will, et al., U.S. Patent Nos. 4,801,514, 4,911,994, 5,032,477 5,262,251, 5,312,712.

Attempts have been made to move the metal layer between the thermally shrinkable polymer film layer and the pressure-sensitive adhesive layer between self-supporting polymer film layers having heat shrinkability. One such configuration without the use of shrinkable polymer films is described in US Patent 5,292,566 to Sharklett, III. A major limitation of this configuration, however, is that the adhesion of the polymer layer to the metal is weak and the metal layer is prone to rupture by on-line squeezing forces used to impart lot and date code information to the label. It is known that the pieces of the broken metal layer penetrate the relatively soft pressure-sensitive adhesive layer to short-circuit the battery, thereby wasting electric energy.

Another approach that has been attempted commercially has been to replace the topmost heat shrinkable polymer film layer 2 " with an ultraviolet treated varnish. Such a construction is described in U.S. Patent No. 5,190,609 to Lin et al. Such labels are only limitedly tolerated, and such coatings have proven to be weak junctions that reveal poor resistance to abrasion and resistance to changes in ambient conditions.

The multi-layer construction also tends to harmonize the shrinkage characteristics of various polymer films, thereby causing no slip between adjacent polymer film layers having heat shrinkability during heat shrinkage. If such a problem is not solved, graphics can be damaged, wrinkled, or thinly cracked. The dual configuration also has a problem that the label is lifted from the battery case and easily worn out in response to changes in the surrounding environment.

It would be desirable to provide a single ply construction of a pressure-sensitive adhesive for packaging the battery case. The monolayer structure will cost less than the multilayered label structure currently used.

Applicable single-layer battery labels should be able to have a lifetime of more than 5 years without exposing them to environmental stresses, including periodic exposure to temperatures above 150 ° F and humidity close to 100%. More importantly, a single-layer label can adequately withstand the manufacturing difficulties without the benefits provided if other layers with features that can be used to modify or add the properties of the single layer to account for manufacturing and environmental stresses .

As a result, the single-layer label configuration maximizes the functional cell capacity by reducing the thickness of the label, thereby not only being able to concentrate more energy in the entire cell configuration having a fixed extrinsic size during battery manufacturing, but also the cost and manufacturing advantages Nevertheless, there is a continuing need in the art to provide effective single layer labels.

Portions of the drawings labeled " Prior Art " illustrate triple and double label configurations illustrating conventional adhesive battery label configurations.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a perspective view showing the details of the single layer label layers of the present invention according to the relationship between a battery case and a label. FIG.

1B is a view showing the same configuration as that shown in Fig. 1A except that the adhesive layer extends around the periphery of the label.

Fig. 2 is a view showing a single-layer label of the present invention which surrounds the peripheral portion of a battery in a synchronized relationship; Fig.

Fig. 3 shows the heat shrinkage of the end of the label protruding over the opposite end of the cell by applying heat. Fig.

Figure 4 illustrates one means of attaching a label to a cell using the single layer label of the present invention.

According to the present invention, there is provided a single layer label for use in a battery comprising ends facing opposite peripheral shells surrounding a core providing direct current electrical energy. The label is transparent and self-supporting, is oriented in a single axis, is heat shrinkable, and is formed of a polymer film facestock or backing having a width and a length. The width of the support layer provides first and second edges in the longitudinal direction facing each other at its ends and the support layer sufficiently encloses the case of the cell so that the first and second sides at least abut each other. The length of the support layer provides first and second opposing peripheral edges whose length is greater than the length of the battery case and which is beyond the length of the battery case when wrapped in the battery case at its end. An opaque alkali-resistant, electrically non-conductive coloring layer covering any visual indicia printed on the lower surface of the support layer is also printed on the lower surface of the support layer and supported by the support layer. The electrically non-conductive pressure-sensitive adhesive layer preferably extends at least along the length of the first and second sides of the support layer, preferably at the periphery of the support layer and at least at the opposite end of each of the cells, And extends sufficiently far inwardly from the opposing edges of the support layer. The pressure-sensitive adhesive is preferably applied on the entire colored layer. The pressure sensitive adhesive has sufficient shear strength or adhesion to prevent heat shrinkage of the support layer at least at the periphery of the cell and has sufficient peel adhesion strength to prevent the label from lifting from the case along the length of the cell.

The label is applied to the outer surface of the battery case and attached to the case by contact of the pressure-sensitive adhesive. The label then surrounds the battery case with first and second sides adjacent to the third and fourth sides protruding at least above the battery case. The projecting end of the label is contracted to wrap the opposite end of the cell by the action of heat applied to the heat-shrinkable film.

The colored layer is intended to achieve the object of the present invention and is considered to be alkaline if it does not react upon exposure to the action of 7.2N KOH for 24 hours in the penetration test and if the resistance is less than about 560 megohms (560x10 ⁶ ohms) If it is large, it is considered to be electrically resistant.

Preferred adhesives in the present invention are solvent-based acrylic pressure-sensitive adhesives. Emulsion or hot melt pressure sensitive adhesives can also be used effectively. Preferred in the present invention is that the pressure sensitive adhesive has a peel strength or peel adhesion strength of at least about 2 Pli (pounds per inch), preferably about 2 to 5 Pli, a shear force of at least 4,000 minutes, preferably about 4,000 to 10,000 minutes, Pli < / RTI > and preferably between about 2 and 4 Pli.

The preferred support layer has a contraction coefficient in the circumferential or circumferential direction of about 60%, preferably about 20% to 60%, more preferably about 40-50%. The contraction occurs along the width of the support layer. A preferred support layer in the present invention is a polyvinyl chloride film having a thickness of approximately 2 mils. And oriented in a transparent uniaxial direction.

According to the present invention, a single-layer label for a battery and a cell having such a label are provided.

The cell to which the single-layer label of the present invention is applied includes a cell having cylindrical "AA", "AAA", "C" and "D" sizes. The label used for such a battery is larger than the length of the battery so that the end of the label overlaps the opposite end of the battery when the label shrinks. The label of the present invention can also be used for any other battery which does not need to consider the electrical aspect of the cell having cylindrical AA, AAA, C and D sizes. Other such battery configurations include, but are not limited to, the popular 9-volt battery.

As shown in Figs. 1A, 1B, 2 and 3, a typical cylindrical battery 10 is composed of a core 12 and an electrode 14, preferably formed of an alkaline material and providing electrical energy. The core 12 and the electrode 14 are both enclosed by a cylindrical casing 16 providing a cathode end cap terminal 18 and a cathode end cap terminal 20. The anode is electrically connected to the core 12 and the cathode is electrically connected to the electrode 14. The case 16 is electrically insulated from the end cap 20 by an annular insulator 22 made of a suitable non-conductive material. The positive and negative end caps 18, 20 are in contact with the inside of the single layer battery label 24 of the present invention.

As shown in Figures 1A and 1B, the single layer cell label 24 is made up of three major layers. That is, the heat-shrinkable layer 26 that can be self-supporting and the alkali-resistant colored layer 28 that is electrically non-conductively supported at least at the portion of the battery case that covers the battery segments 16 and 20, And a pressure-sensitive adhesive layer 30, which is electrically non-conductive, in a portion covering the element. The pressure sensitive adhesive layer (30) extends along first and second sides (32, 34) parallel to the axis of the battery. The sides 32 and 34 can be overlapped with each other. Adhesive is applied to provide reliable pressure-reducing adhesive force to the four sides in contact with the battery case. 1A, preferably, a pressure-sensitive adhesive is applied to the outer periphery of the label 24 so as to cover the first and second sides 32, 34 and the third and fourth sides 36, 38 to provide. More typically, the pressure sensitive adhesive layer 30 covers the entire surface of the layer 26, as shown in Fig. The pressure-sensitive adhesive layer 30 is electrically non-conductive at least in the portion contacting the battery elements 18 and 20 in order to prevent leakage of water from the positive electrode to the negative electrode of the battery. The coloring layer 28 and the facestock or backing 26 of the heat shrinkable polymer are also electrically nonconductive at the portions of the battery 10 that are in electrical contact with the positive and negative electrodes. The nonconductive colored layer, which removed the fragile metal film deposited in the previous vacuum, plays a crucial role in the use of the support of the monolayer.

Another decisive factor in providing a single layer battery label is the appropriate choice of front face with production parameters in mind. It is necessary to provide a dense structure having a function which has been used in the past and which has been used in the past by using a front surface on which a graphic is printed on a self-supporting monolayer and an adhesive is applied on the printed graphic. In the past, in using multiple self-supporting layers, one layer could supplement or modify another layer or add some attributes to make a label at the time of manufacture. In the present invention, the monolayer must provide multilayer functionality while minimizing the thickness of the label. This should be possible without increasing production costs. This is because, if a single layer is used, if the production cost is greatly increased, an increase in the production cost will nullify the advantage of the fault. In addition, the single support film is thermally shrinkable, yet sufficient to withstand the degradation when the multicolor print consistency is repeated in a variety of printing areas where a large number of colors used to form informational content and aesthetic graphics are printed It should be inelastic. For such operation, six to ten or more colors will be added to the film. The film should not sway backwards. Otherwise it will fall into print clarity that interferes with commercially unacceptable multicolor print matches. At the same time, the film must have some retractive force in the machine direction so that the end of the label can overlap the end of the cell when applying heat without compromising the graphics engraved on the film. If there is too much flaw or shrinkage, the film may be pulled out of the suture and create another unacceptable consequence, such as exposing a sticky glue. In addition, improper shrinkage of the suture portion results in an undesirable appearance due to hearing. With this in mind, in view of the production rate of producing about 800 cells per second in the labeling machine with an "AA" size and producing more than 600 cells per second with an "AAA" size, I have come to conceive of the enemy.

The front or backing layer 26 is for a single layer construction and is a polymer film with a single axis. It is located around the periphery along the width of the support layer in a direction perpendicular to the axis of the battery. In that direction, that is to say the contraction from the machine direction or from the first side 32 toward the second side 34, is about 60%, generally about 20 to 60%, preferably about 40% To about 50%, and most preferably about 40% to about 45% for a small battery, and about 40% to about 50% for a large battery.

The amount of shrinkage remaining at the time of storage should not exceed about 10%, preferably not more than 8%, more preferably not more than 3%.

Some shrinkage can also occur in the axial direction perpendicular thereto. The shrinkage from one direction to the perpendicular direction thereof is from -2 to 5%, preferably from 0 to 3%, more preferably from approximately 0 to 1%. The negative shrinkage refers to the kidney.

The presently preferred mechanical properties of the film have a tensile strength of approximately 15 Kpsi in the machine direction and a modulus of elasticity of 400 Kpsi in the machine direction with an elongation of 77% in the machine direction, both of which are determined according to ASTM D882-91 (Test Method A) .

The heat-shrinkable film layer 26 preferred in the present invention is a substantially single-axis polyvinyl chloride film manufactured by Americal Mirrex Corp. of New Castle, Del., Having a thickness of approximately 2 mils.

Preferred films in the present invention are polyesters oriented in one axis in the machine direction having a thickness of approximately 1 to 3 mils., Preferably a thickness of approximately 2 to 3 mils., More preferably approximately 2 to 2.5 mils. Vinyl chloride film.

Other heat-shrinkable films that can be used in addition to polyvinyl chloride films include, but are not limited to, polyvinyl fluoride films, vinylidine fluoride films, polypropylene films, and the like. Other films include the polypropylene film described in U. S. Patent No. 5,190, 609 to Lin et al. The front surface 26 serves as a magnetically supported carrier for the colored layer 28 and the pressure-sensitive adhesive layer 30. [

Between the colored layer 28 and the film 26, a mark having other information content formed by the ink such as decorative graphic, bar code, production information and the like is included. Although the surface conductivity and the alkali resistance are not critical to such inks, the resistance to alkali (KOH) penetration is preferably at least equal to the electrical resistance of the colored layer 28 and / or the pressure-sensitive adhesive layer 30 Is provided. This makes it unnecessary to take into account any minor defects such as battery leakage due to short circuit when the elements of the label, the coloring layer, and the pressure sensitive adhesive layer contact the anode and cathode elements of the cell.

The cathode and the membrane of the label which are in contact with the anode should not react to the action of the alkali or be alkali-resistant. The term "alkaline" means that there is no appreciable change in appearance when exposed to the action of 7.2N KOH for approximately 24 hours. All of the elements 28, 30 electrically contacting the positive and negative electrode cell elements must also be electrically non-conductive. The term " electrically non-conductive " means that it has a resistance greater than about 560 megohms (560x10 ⁶ ohms). Only the elements of the layer connecting the positive and negative electrodes of the battery need to be electrically non-conductive, but as noted above, it is preferred that all layers 28,30 are electrically non-conductive.

The colored layer 28 is supported by the support layer 26 and is an alkali-resistant and electrically non-conductive layer that is opaque and provides a coating that forms the background for the label, The ink is formed with an alkaline resistance in which a coloring matter is deposited from the ink. The films that are layered side by side in a single color or in multiple colors may include a colored layer 28. The colored layer 28, which forms the background and the background, is printed on the lower surface of the self-supporting transparent layer 26.

The preferred alkaline and electrically non-conductive inks in the present invention are those made in Zeneca Specialty Inks, New Jersey. Suitable are Zeneca NDX-1467 (copper), NSX-1442 (silver), NKX-2155 (black) and NWX1596A (white). Copper and silver inks provide a metallic shape in the pearl system to replace the conductive layer of metal found in prior art label configurations. Preferred in the present invention is that the colored layer 28 is continuous on the back side of the transparent film 26 of the label 24. As noted, however, portions of the colored layer 28 that are in electrical contact with the anode 20 and cathode 22 may be discontinuous or multilayered, provided that they are alkaline and electrically non-conductive.

1A, the pressure sensitive adhesive layer 30 may extend beyond the entire surface of the film 28. In this case, The adhesive layer 30 may also extend only along the sides 32, 34 or may have a width sufficient to securely contact the case around the cell around the periphery of the label, as shown in Figure 1B . The adhesive force applied to the battery case should be sufficient such that no shrinkage of the label occurs at the adhesive portion except at the portion of the label beyond the end of the cell. As shown in Figs. 2 and 3, when exposed to heat, the elongated ends shrink and overlap and are adhered to the opposite ends of the cell by the pressure sensitive adhesive. In the case where the pressure sensitive adhesive layer 30 extends only along the sides 32 and 34 forming the suture portion 42, the graphic should be designed in consideration of the manner in which the layer 26 shrinks in the axial direction.

The pressure sensitive adhesive may be applied in the form of a solvent, emulsion or suspension, or in the form of a hot melt. The pressure sensitive adhesive should have sufficient shear or adhesive strength to prevent excessive shrinkage of the label adhered to the cell case due to the action of heat after placing the label on the cell, which is the substrate. In other words, it must have sufficient adhesive force to prevent the front face from being lifted from the battery and a fixing force to allow the label to properly adhere to the battery case while affixing the label.

A preferred pressure sensitive adhesive comprises a solvent-based acrylic adhesive manufactured by Ashland Chemical Company, Inc. of Columbus, Ohio, product number 1860Z45 modified by the addition of an antioxidant. Another suitable solvent acrylic pressure sensitive adhesive is Polytex ^TM 7000, described in US Pat. No. 5,221,706 to Mallya et al., Manufactured by Avery Chemical Division of Avery Dennison Corporation. Suitable emulsion pressure sensitive adhesives are those described in Lin et al., U.S. Patent No. 5,221,706.

Preferred to have a total balance of adhesive properties and suitably label and hold the battery case properly is that the adhesive has a peel strength or adhesive strength of at least about 2 Pli, more preferably about 2 Pli to about 5 Pli And a width of 12 inches per minute after 20 seconds in the 2-mil polyester support layer, measured using PSTC # 1 (Pressure-Sensitive Tape Counsel Test # 1) The test was conducted with a sample having a weight of 500 grams at 0.5X0.5 " according to Test # 7, and the result was a shear force that resisted at least 4,000, preferably about 4,000 to 10,000 minutes with 2,000 grams per cubic inch loaded , At least about 2 Pli, preferably between 2 and 4 Pli at a 12 inch peel rate per minute for a 1 " wide loop in stainless steel. It has a fake.

Figure 4 shows one labeling operation. The label 24 placed on the plate publication 44 is flashed and "grabbed" on the surface of the battery 10 that is discharged from the plate publication 44 through the relatively pointed dispensing edge 46. The battery 10 is rotated by the roll 48 during operation. And the label 24 is wrapped around the edge of the cell to form an adjacent (Figure 3) or somewhat overlaid suture 42. [ The label is firmly fixed to the battery case to shrink the battery case, and preferably has a shrinkage resistance function along the length and width of the battery case when heat is applied from the heat source 50, usually from the air knife. The adhesive also prevents damage to the labels contained between the layers 26, 28 due to heat shrinkage of the front surface 26. Removal of the adhesive from the sides 36, 38 is possible when the support layer exhibits a low shrinkage in the direction of the battery axis.

2 and 3, once the label is wound and attached to the cylindrical shell of the cell 10, the end 40 of the label extends beyond the cylindrical casing of the cell 10, The cathode 18 and the cathode (not shown). As shown in FIG. 3, when heat is applied, the label shrinks so that the ends of the label wrap the positive and negative electrodes of the battery, and if the pressure sensitive adhesive is present, the label sticks to the battery case at both ends. Alternatively, sufficient contraction force may be imparted to secure the overlapping portion of the label to the surface of the battery end. In this embodiment, the adhesive force of the pressure-sensitive adhesive prevents the label from moving due to the shrinkage force along the cylindrical case so as not to damage the label, and never to cause a hole in the sealing portion 42 due to peripheral contractility. In summary, the exposed ends of the cells are pulled tightly to the cathode and anode of the cell by thermal contraction due to heat shrinkage and are attached to the cathode and anode by a pressure sensitive adhesive, so that the graphic remains intact and remains intact while labeling the cells at low cost do.

Claims (35)

As a single layer label attached to a battery, which is defined by the axis of the battery and the ends facing perpendicularly to the axis, the battery comprising a long outer case extending in the longitudinal direction of the battery and a core providing direct electrical energy in the case , (a) an inner surface and an outer surface facing the battery case; A width providing a first side extending parallel to the axis of the battery and an end facing the second side; And at least partially transparent, self-supporting and substantially cylindrical, having a third side extending beyond the opposite ends of the cell and extending perpendicularly to the axis of the cell and a length at the end facing the fourth side A heat-shrinkable polymeric film support layer oriented in one axis, The width of the support layer is sufficient for the support layer to surround the outside of the battery case and contact the first side and the second side at least adjacent to each other and the length of the support layer is set such that, It is sufficient to wrap the opposite ends of the cell, The support layer is a support layer mainly having heat shrinkage in the width direction up to 60% of the width direction, (b) an opaque colored layer comprising an alkaline, electrically non-conductive ink applied to an inner surface of the support layer and supported by the support layer, The colored layer is an opaque colored layer in which there is no detectable change upon exposure to the action of 7.2N KOH for 24 hours; And (c) a pressure-sensitive adhesive layer which is an electrically non-conductive, extended and applied across the colored layer at least along the first side and the second side, The pressure-sensitive adhesive layer may have a peel strength sufficient to prevent the applied label from being lifted from the battery case, and to move to the first transition case of the support layer to which the adhesive is applied compared to the second side of the support layer coated with the adhesive when the heat- A pressure-sensitive adhesive layer having a sufficient shear strength Lt; / RTI > 2. The single layer label of claim 1, wherein the support layer has a retraction force of 40 to 50% along the width of the support layer. The single-layer label of claim 1, wherein the support layer has a shrinkage force of 40 to 45% along the width of the support layer. 4. The single-layer label according to any one of claims 1 to 3, wherein the support layer has a film formed of polyvinyl chloride oriented in one axis and has a thickness of 1 to 3 mils. 4. A single-layer label according to any one of claims 1 to 3, wherein the support layer has a film formed of polyvinyl chloride oriented in one axis and has a thickness of 2 to 2.5 mils. 4. The pressure-sensitive adhesive according to any one of claims 1 to 3, wherein the pressure-sensitive adhesive has a peel strength of 2Pli or more, a shear strength of 4000 minutes or more, and an acrylic resin having a loop tack of 2Pli or more at a rate of 12 inches peeled off per 1 inch loop on stainless steel A single layer label that is an adhesive. The single-layer label according to any one of claims 1 to 3, wherein the pressure-sensitive adhesive is an acrylic adhesive having a peel strength of 2 to 5 Pli and a shear strength of 4,000 to 10,000 minutes. 4. The single-layer label of any one of claims 1 to 3, wherein the pressure sensitive adhesive further extends along the third and fourth sides of the support layer. The single-layer label according to any one of claims 1 to 3, wherein a substantially entire surface of the colored layer is covered with the pressure-sensitive adhesive layer. 4. The label according to any one of claims 1 to 3, (a) an inner surface and an outer surface facing the battery case; A width providing a first side extending parallel to the axis of the battery and an end facing the second side; And a length which is longer than the length of the cell and which provides a third side extending perpendicularly to the axis of the cell and an end facing the fourth side, the thickness being between 1 and 3 mil, A support layer of a heat-shrinkable polymer film supported and oriented substantially in one axis, The width of the support layer is sufficient for the support layer to wrap around the outer shell of the cell and to contact the first side and the second side at least adjacent to the outer casing of the cell, and the length of the support layer, The third side and the fourth side are sufficient to cover the opposite ends of the battery, Wherein the support layer has a support layer in which heat shrinkage occurs mainly in the direction of the support layer up to 60% of the width direction of the support layer, (b) an opaque colored layer comprising an alkaline, electrically non-conductive ink applied to an inner surface of the support layer and supported by the support layer, The colored layer is an opaque colored layer in which there is no detectable change upon exposure to the action of 7.2N KOH for 24 hours; And (c) an acrylic pressure-sensitive adhesive layer having electrical non-elongation applied over at least the coloring layer along the first side and the second side, The pressure-sensitive adhesive layer may have a peel strength of 2 Pli or more sufficient to prevent the applied label from being lifted from the battery case, and a second side of the support layer to which the adhesive is applied compared to the second side of the support layer to which the adhesive is applied, Sensitive adhesive layer having a shear strength of 4,000 minutes or more, Lt; / RTI > 11. The single layer label of claim 10, wherein the support layer has a film formed of polyvinyl chloride oriented in one axis and has a thickness of 2 to 2.5 mils and a shrinkage force of 40 to 45% in the width direction of the support layer. A battery labeled battery comprising an elongated outer case defined by an axis and ends facing perpendicularly to the axis and a core providing direct electrical energy in the case, (a) an inner surface and an outer surface facing the battery case; A width providing a first side extending parallel to the axis and an end facing the second side; A heat-shrinkable polymeric film support layer that is at least partially transparent, self-supporting and oriented in one axis, having a third side extending perpendicularly to the axis and a length providing an end opposite the fourth side, Wherein the first side and the second side are fixed at least adjacent to each other by the pressure-sensitive adhesive, and each of the first side and the second side is substantially prevented from moving relative to each other when the support layer is shrunk to the battery case; The facing third and fourth sides are heat shrinkable by wrapping opposite ends of the battery; The supporting layer is mainly composed of a support layer in which heat shrinkage occurs mainly in the width direction up to 60% (b) an opaque colored layer comprising an alkaline, electrically non-conductive ink applied to an inner surface of the support layer and supported by the support layer, The colored layer is an opaque colored layer in which there is no detectable change upon exposure to the action of 7.2N KOH for 24 hours; And (c) a pressure-sensitive adhesive layer which is applied by extending the coloring layer at least along the first side and the second side and is electrically non-conductive to attach the label to the battery case, Wherein the pressure sensitive adhesive layer has a peel adhesion sufficient to prevent the first and second sides from lifting in the cell case and a shear sufficient to substantially prevent movement of the first side of the support layer relative to the second side of the support layer during thermal shrinkage of the support layer Pressure-sensitive adhesive layer having strength Labeled battery. The battery according to claim 12, wherein the one axis oriented support layer is capable of shrinking to less than 60% in the width direction of the support layer before shrinkage. 13. A cell according to claim 12, wherein said one axis oriented support layer is capable of shrinking from 40 to 50% in the width direction of said support layer prior to shrinkage. 15. A cell according to any one of claims 12 to 14, wherein the support layer is formed of a polyvinyl chloride film oriented in one axis and has a thickness of 1 to 3 mils. 15. A method according to any one of claims 12 to 14 wherein said support layer is formed of a polyvinyl chloride film oriented in one axis and has a thickness of 2 to 2.5 mils and a shrinkage force of 40 to 45% battery. 15. The method of any one of claims 12 to 14, wherein the pressure sensitive adhesive has a peel strength of at least 2 Pli, a shear strength of at least 4,000 minutes, and a loop geometry of at least 2Pli at a peel rate of 12 inches per minute on a stainless steel battery. 15. The battery according to any one of claims 12 to 14, wherein the pressure-sensitive adhesive is an acrylic adhesive having a peel strength of 2 to 5 Pli and a shear strength of 4,000 to 10,000 minutes. A pressure sensitive adhesive according to any one of claims 12 to 14, wherein the pressure sensitive adhesive further extends along the third and fourth sides of the cell and at least glues the support layer at the third and fourth opposite sides of the cell Battery to adhere. A pressure-sensitive adhesive sheet according to any one of claims 12 to 14, wherein the pressure-sensitive adhesive layer covers substantially all the colored layers, and the support layer is adhered to the opposite end of the battery at least at the third and fourth sides The battery being fixed. 15. The battery according to any one of claims 12 to 14, wherein the pressure-sensitive adhesive layer covers substantially all the colored layers. 15. The method according to any one of claims 12 to 14, (a) an inner surface and an outer surface facing the battery case; A width formed at a first side extending parallel to the axis and at a second end facing the second side; And a length formed at a third edge extending perpendicular to the axis and a fourth edge opposite to the first edge, the thickness being between 1 and 3 mils, the at least partially transparent self-supporting heat shrinkable polymer As the film supporting layer, The label covers the edge case of the battery. The first side and the second side are adhered and fixed at least adjacently to the case of the battery by a pressure-sensitive adhesive, and the facing third side and the fourth side are opposite to each other, And the support layer is a support layer in which heat shrinkage occurs mainly in the width direction up to 60% of the width direction of the support layer before heat shrinkage, (b) an opaque colored layer comprising an alkaline, electrically non-conductive ink applied to an inner surface of the support layer and supported by the support layer, The colored layer is an opaque colored layer in which there is no detectable change upon exposure to the action of 7.2N KOH for 24 hours; And (c) extending said colored layer along at least the first side and the second side at least enough to attach said label to said battery case at said first side and said second side, and attaching said label to said battery case Acrylic pressure-sensitive adhesive layer of an electrically non-conductive type, Wherein the pressure sensitive adhesive layer has a peel strength sufficient to prevent the attached label from lifting from the battery case and a reduced pressure having a shear strength sufficient to substantially prevent movement of the first side of the support layer relative to the second side of the support layer during thermal shrinkage of the support layer Adhesive layer Labeled battery. (a) a battery, which is defined by an axis of the battery and a cathode terminal and a cathode terminal facing perpendicularly to the axis, the battery comprising an elongated outer case extending in the longitudinal direction of the battery and a core providing direct electrical energy in the case ; (b) on a web having a release surface (i) an inner surface and an outer surface facing the battery case; A width providing a first side extending parallel to the axis of the battery and an end facing the second side; At least partially transparent, self-supporting, substantially one, having a third side extending beyond the opposite ends of the cell and extending perpendicularly to the axis of the cell and a length at the end facing the fourth side As the heat-shrinkable polymer film support layer, The width of the support layer is sufficient for the support layer to surround the outside of the battery case and contact the first side and the second side at least adjacent to each other and the length of the support layer is set such that, The support layer being sufficient to cover the opposite ends of the cell, wherein the support layer is a support layer in which heat shrinkage occurs mainly in the width direction up to 60% in the width direction of the support layer, (ii) an opaque colored layer comprising an alkali-resistant, electrically non-conductive ink applied to the inner surface of the support layer and supported by the support layer, the colored layer being exposed to the action of 7.2N KOH for 24 hours An opaque coloring layer with no appreciable change in appearance; And (iii) a pressure-sensitive adhesive layer which is an electrically non-conductive adhesive applied over at least the coloring layer along the first side and the second side, The pressure-sensitive adhesive layer may have a peel strength sufficient to prevent the applied label from being lifted from the battery case, and to move to the first transition case of the support layer to which the adhesive is applied compared to the second side of the support layer coated with the adhesive when the heat- A pressure-sensitive adhesive layer having a sufficient shear strength ≪ / RTI > (c) applying the label to the case of the outer shell of the cell from the web for bonding; (d) attaching and enclosing the label to the outer casing so that the first side and the second side meet adjacent each other, or the third side and the fourth side overlap over opposite ends of the cell Forming an overlap extension; (e) applying heat to the polymer film and the overlap extension to cause heat shrinkage to wrap over the positive and negative electrodes of the battery Wherein the method comprises the steps of: 24. The method of claim 23, wherein the pressure sensitive adhesive extends to the third and fourth sides and the overlap extension is bonded and bonded to the positive and negative electrodes according to shrinkage. 25. The method of claim 23 or 24, wherein the label is dispensed as the label passes over a relatively sharp edge. The method according to claim 25, wherein the distributed label is attached to the battery case with the first side and the second side as a head, and the battery case is rotated with respect to the axis to surround the battery case. 25. The method of claim 23 or 24, wherein heat providing shrinkage of the label is emitted from the air knife. 25. The method of claim 23 or 24, wherein the support layer has a shrinkage force of 40 to 50% in the width direction of the support layer. The method of claim 23 or 24, wherein the support layer has a shrinkage force of 40 to 45% in the width direction of the support layer. 25. The method of claim 23 or 24, wherein the support layer is formed of a polyvinyl chloride film oriented in one axis and has a thickness of from 1 to 3 mils. 25. The method of claim 23 or 24, wherein the support layer is formed of a polyvinyl chloride film oriented in one axis and has a thickness of from 2 to 2.5 mils. 26. The method of claim 23 or 24 wherein said pressure sensitive adhesive is an acrylic adhesive having a peel strength of at least 2Pli and a shear strength of at least 4,000 minutes and a loop tie of at least 2Pli at a rate of 12 inches per minute per 1 inch loop over stainless steel. The method according to claim 23 or 24, wherein the pressure-sensitive adhesive is an acrylic adhesive having a peel strength of 2 to 5 Pli or more and a shear strength of 4,000 to 10,000 minutes or more. The method according to claim 23 or 24, wherein a substantially entire surface of the colored layer is covered with the pressure-sensitive adhesive layer. 24. A battery labeled by the method of claim 23 or 24.